Electric valve control circuits



June' 14, 1949. M. E. BIVENS 2,473,238

ELECTRIC VALVE CONTROL CIRCUITS Filed April \19, 1947 v 2 Sheets-Sheet 1 Inventor: Maurice El. Bivens,

by Wv JW His Attorney Fug la June 14, 1949. M. E. BIVENS ELECTRIC VALVE CONTROL CIRCUITS 2 Sheets-Sheet 2 Filed April 19, 1947 m nw .gvvv 6 mm t5 0 T u vw A nw .5 .lWaU Vv mm b was.

Patented June 14, 1949 ELECTRIC VALVE CONTROL CIRCUITS Maurice E. Bivens, Schenectady, N. Y., assignor to General Electric Company, a corporation of New York Application April 19, 1947, Serial No. 742,754

20 Claims. (Cl. 315-246) My invention relates to electric valve control circuits and more particularly to new and improved electric valve control circuits for electric translating apparatus which effect intermittent energization of a load circuit and which not only control accurately the period of each energization of the load circuit but also control accurately the interval of time between successive energizations of the load circuit.

In the field of resistance welding, electric valve control circuits have been used, not only to con trol the timed applications of welding current, but also to control the magnitude of the welding current by the phase shift method in order to obtain the desired heating effect of the welding current on the work parts. Also in order to prevent saturation of the welding transformer such electric valve control circuits have been used to obtain synchronous starting of welding current flow, that is, initiation of current flow at the same point of the voltage wave of the source, as well as to obtain current fiow in full cycle steps. As will be pointed out in greater detail below, I provide an improved alternating current electric valve system which, when used as a resistance welding control, operates synchronously to time in full cycle steps the flow of welding current which is adjustable in magnitude by the phase shift method and which also operates to time in full cycle steps the interval of time between successive energizations of the welding circuit.

When sine wave control voltages are applied to the control elements of a pair of electric valves connected in reverse parallel relationship for transmitting alternating current to a load device, it is not always possible to obtain balanced conduction through the valves because of variations in the critical control voltage characteristics of these electric valves. as well as due to the differences in cathode voltages resulting from the differences in their connections with the supply circuit. Thus, for example, in a resistance welding circuit one of the cathodes of the pair of electric valves is tied to one terminal of the source of supply, whereas the other terminal is tied to one of the terminals of the welding transformer and is consequently subjected to abrupt voltage variations at the time the valve becomes nonconducting. By increasing the magnitude of the sine wave control voltage, its wave front may be made suificiently steep to reduce to a low value variations in the firing times of such valves but this is productive of other operating difiiculties and also increases the size and cost of the control equipment employed.

Furthermore, in such electric valve circuits where timing functions depend on the charge and discharge of a timing capacitor it is often necessary to increase the size of the capacitor so that its discharge time may be suitably lengthened without increasing the resistance of its discharge circuit to so high a value that leakage discharge currents seriously interfere with the accurate timing operation desired. Furthermore, when using a hot cathode rectifier the self-generating voltage of the rectifier may produce a charge on the capacitor which will give a false or inaccurate timing operation to the system of which it forms a part.

Also in such electric valve control circuits the maximum speed of its operation is often dependent on the operating times of certain electromechanical switches and for this reason it is desirable to provide a system in which time-on and time-off operations are accurately determined solely by electronic means having no moving parts. This desirable high speed operation of a system also makes it necessary to charge the timing capacitor or capacitors at a high rate which of necessity requires a special charging circuit other than the grid-to-cathode circuit of one of the electric valves which, at the same time, may serve another function in the control circuit.

It is an object of my invention to provide an electric valve control circuit in which relay elec-' tric valves of low current carrying capacity, and consequently having less variations in their critical control voltage characteristics, are employed in circuits where their cathodes are not subjected to abrupt voltage changes for producing abrupt or steep wave front control voltages which are applied to electric valves connected in a power circuit and subjected to unbalance firing for reasons indicated above.

It is also an object of my invention to provide an electric valve control circuit in which a timing capacitor of large capacity is quickly charged through a hot cathode rectifier connected in circuit therewith and a source of voltage which opposes the self-generated voltage of the rectifier and establishes the voltage of one terminal of the capacitor relative to another part of the circuit to which the control voltage of the capacitor is applied so that infallible operation of the systrol system by embodying therein an improved electronic timing circuit which effects the intermittent energization of a load circuit and not only controls the period of each energization thereof but also controls the interval of time between successive energizations of the load circuit without requiring the use of electro-mechanical relays which by reason of their comparative slow operating characteristics limit the maximum speed of operation of any system of which they form a part.

It is also an object of my invention to provide a new and improved electric-valve control system particularly suited for use in theresistance' welding field.

Further objects of my invention willbecome apparent from a consideration of the followin description of the embodiments thereof shown in the accompanying drawings. Figs. 1a and 1b of these drawings, when. assembled with the broken circuits along the: margins thereof connected in accordance with" corresponding reference numerals applied thereto,is a diagrammatic representation of one-embodiment of my invention as applied to a resistance spot and line welding control, and Fig. 2 isi a diagrammatic representation of a portion of thercircuit of Fig. 1a illustrating the use of a-cathode follower circuit to prevent negative grid current fiow'through one of the gaseous electric valves ofthe system rendering uneven the scale indicationsior'equal timadjustmcntsof the discharge circuit of said capacitor.

In accordance with fthe'illustrative embodiment of my invention, a pair of electric'valves reversely connected in parallel with one another control the flow ofalternating welding current from an alternating current supply circuit to the primary winding of a'welding transformer having itssecondary winding connected to a pair of cooperating resistance welding electrodes. These power line valves are controlled by reversing the phase of an alternating control voltage applied to the control elements of their firing valves by means of relay'valves which are rendered conducting and non-conducting by the application of sine wave voltages of the supply circuit to the control elements of these relay valves. These sine wave voltages are selectively and automatically impressed on the control elements of the relay valves so that the more negative voltage is at all times controlling. The point in the positive half cycle of anode voltage at which the relay valves become conductive is determined by a sine wave voltage of a phase shift circuit, which voltage is normally inefiective by reason of a sine wave bias voltage and becomes effective when the bias voltage is neutralized or overcome by a sine wave turn-on voltage derived from an oscillating circuit.

This oscillating circuit is energized from the supply circuit when a turn-on valve becomes conducting and disappearswhen a timing valve becomes conducting a predetermined time later. Both the turn-on and timing valves are controlled by applying to their control elements the lagging voltage drop across a keying valve which is connected through an inductive circuit with the supply circuit so that a positive half cycle of anode voltage is applied tothe keying valve during one half cycle'of thesource and during the next half cycle of the source a positive anode voltage is applied'to theanodes of the turn-on and timing valves. The timing valve operates after a time delay determined by a capacitor iii) which is continuously discharged through a discharge circuit and which is charged from the supply circuit through a hot cathode rectifier to a predetermined voltage while the keying valve is non-conducting. The self-generating voltage of this rectifier is overcome by a source of voltage which also determines the potential of the control element connection thereof with the timing valve relative to the cathode of this valve.

The keying valve is rendered conductive in like trailing fashion by an initiating valve connected in parallel with the turn-on valve. Once conduction is initiated. by the keying valve, it and the turn-on valve conduct alternatively since the control element of the keying valve is also connected to be responsive to the lagging voltage drop across the turn-on valve. This mutual trailing operation of the keying and turn-on valve is interrupted when the timing valve by its conduction renders the oscillating-circuit non-oscillatory and reduces the inductance thereof'in circuit with the turn-on valve to zero or a low value so that'the trailing voltage drop across thexturn-on valvedi'sappears and the keying valve cannot again become conductive.

The initiating electric valve has two control elements, one of which is: connected to apply a starting potential thereto. at the beginning of a positive half cycle of its anode voltage providing its other control element" will 'permitit to conduct. The other control element is connected to be responsive to the charge on a timing capacitor having a continuously effective. discharge circuit which is adjustable for various times. This capacitor is'charged from a direct current supply circuit through a controlled rectifier which becomes conductivein response topotentials applied to its control element whenever the keying valve is conducting.

The circuit thus described times: the-'current-on periods and the time-off periods between successive time-on periods. 'Byoperating a switch, the initiating valve and its timing circuit may be rendered inactive so that the operation of another switch will cause the remainder-of the circuit to time one current-on period as against the continued succession of time-on and time-off periods produced when the first-mentioned switch is closed.

My invention will be better understood from the following detailed description of the embodiment thereof diagrammatically illustrated in Figs. 41 and lb combined.

As shown in these figures, the. load or welding circuit 1 is energized from a source of alternating current 2 through a supply circuit 3 and electric translating apparatus, comprising .electric valve means 4, a conductor 5 and a welding transformer 6. The supply circuit 3 is connected with the sourc of supply 2 through manually operable switches 7. Although I have referred to the welding circuit or load circuit as being that portion of the circuit connecting the secondary winding of the welding transformer to the welding electrodes, it is obvious that this load circuit may be as readily considered as also including the welding transformer 6 and its connected conductor 5.

Electric valve means 4=may comprise, as illustrated, a pair of electric power valves 8 and 9 which are reversely connected inparallel to supply alternating current from thesupply circuit 3 to the load circuit. The electric valves may be of any of the types well known in the art, but

as illustrated each comprises an anode ID, a

mercury pool cathode II, and an immersion igniter type control element [2. The igniter elements [2 may be formed of a high resistance material and are arranged in the electric valves so that their tips are immersed in the mercury cathode pools of these valves. The elements of each of these electric valves are enclosed in an envelope which preferably contains, as indicated by the dot, an ionizable medium such as a gas or a vapor.

Electric valvesB and 9 are provided with control or firing electric valves l3 and I4. Each of these firing valves is provided with an anode l5, a cathode l6, a control element l1, and a shield grid l9 which is directly connected electrically with its cathode. The elements of each of these firing valves are also enclosed in an envelope which pref erably contains, as indicated by the dot, an ionizable medium such as a gas or a vapor.

The anode-cathode circuit of each of these firing valves l3 and I 4 is connected in series with a current limiting resistor l9 and the contacts of a relay 2| between the igniter l2 and the anode IU of its associated electric valve 8 or 9. The arrangement is such that when a positive anode potential is applied to either of the electric valves 8 and 9, the same positive anode potential is applied to the firing valves i3 and M. These valves are rendered conductive by the application of proper control potentials to their control elements l1 and when conductin connect the control elements l2 of the electric valves 9 and 9 to their anodes in order to initiate conduction through these electric valves during positive half cycles of anode voltage. Thus, the point in the half cycle of positive anode voltage at which electric valves 8 and 9 become conductive depends on the point in the same positive half cycle of anode voltage at which electric valves i3 and I4 become conductive, and this in turn depends on the control potentials applied to the control elements ll of these electric valves.

The control element I1 of electric valve I3 is connected with its cathode l6 through a control element circuit completed through a current limiting resistor '22, a negative self-biasing means comprising a parallel connected capacitor 23 and resistor 24, and a secondary winding 39 of a coin trol transformer 3!. In like manner the control element ll of electric valve I4 is connected to its cathode l6 through a current limiting resistor 2'1, a negative self-biasing means comprising a parallel connected capacitor 28 and resistor 29, and the secondary winding of a control transformer 26. Primary winding 32 of control transformer 26 is permanently connected through a resistor 33 and conductors 34 and 35 to terminals 36 and 3'! of the secondary winding 38 of a transformer 39. It may also be connected through a relay electric valve 49 and conductors 35 and 4! across terminals 31 and 42 of the secondary winding 38 of transformer 39. One terminal of the primary winding 43 of transformer 38 is connected through contacts 44 of a relay 45 and a conductor 46 to one of the supply conductors 3 and the other terminal of this winding is connected through conductors 41, 48 and 49, a winding section 50 of a transformer 5|, and a conductor 52 to the other conductor of the supply circuit 3.

Thus, each time electric valve 49 is rendered conducting or non-conducting the phase of the voltage of supply circuit 3 applied to the primary winding 32 of control transformer 25 is reversed. The arrangement is such that when positive anode potential is applied to firing valve l4 and electric valve 40 is non-conducting the alternating current voltage applied by control transformer 26 by means of the secondary winding 25 connected in the control circuit of electric valve I4 is such as to render electric valve l4 non-conducting. On the other hand, when electric valve 40 becomes conducting, the connection of the primary winding 32 of control transformer '26 is reversed so that the phase of the voltage applied to the control element ll of electric valve 14 by the secondary 25 thereof is such as to render electric valve l4 conducting. When this occurs, the voltage applied to the control element l! of electric valve l4 abruptly changes from some negative value to some positive value, thus providing a steep wave front voltage which immediately causes electric valve l4 and its controlled electric valve 9 to become conductive at the same point in the voltage wave, irrespective of variations in the negative grid characteristics of these electric valves l4 and 9, The abrupt change in potential applied to the control element ll of electric valve M at the time electric valve 49 becomes conducting is of particular importance in that the cathode connection of electric valve I4 is tied to one terminal of the primary winding of welding transformer 5 and thus during operation is subjected to abrupt voltage changes which would result in unbalancing firing of the electric valves 8 and 9 if this steep wave front control voltage were not provided.

In the same manner that the conductivity of electric valve 40 swings the primary terminal 53 of control transformer 26 from terminal 35' to terminal 42 of the secondary 38 of transformer 39, another relay electric valve 54 swings the primary terminal 55 of control transformer 3| from secondary terminal 55 of transformer 39 to terminal 42 thereof. Terminal 55 of the primary winding 51 of transformer 3! is connected through a resistor 58 and a conductor 59 to secondary terminal 56 of transformer 39 and the other terminal of the primary winding 51 is connected through a conductor 99 to secondary'terminal 6| of transformer 39. In each case resisters 33 and 58 not only complete the permanent connection of the primary windings of the control transformers 25 and ti across terminals 36, 3'! and 56, 6! of transformer 39, but also serve as load current limiting means in order to prevent conduction of electric valves 40 and 54 from short circuiting portions of the secondary winding 38 of transformer 39 through terminals 39, 42 and 56, 42 thereof.

When electric valve 54 becomes conducting, the negative alternating bias voltage of winding 30 of transformer 3i abruptly changes to a positive value rendering electric valve !9 conducting at a time when its anode voltage is positive. Conduction through electric valve [3 renders its controlled electric valve 8 conductive to supply alternating current from the supply circuit 3 to the load circuit 5, 6, l.

Relay electric valves 49 and 54 have their cathodes 82 tied directly to conductor 4| which, as illustrated, is connected to ground at 53. Consequently, these relay electric valves will have no disturbance in their cathode potentials due to changes in conductivity of parts of the circuit to which they are connected. It is, therefore,-

possible to control these electric valves with alternating current sine wave voltages of low potential and consequently moderately steep wave front and still obtain balanced firing of these electric valves. The fact that these relay valves 7 4B and 54 are of low capacity also aids in this respect, since their critical control characterisics will vary very little and for all practical purposes may be considered uniform.

Each of the relay electric valves 43 and 54, in addition to its cathode 62, is provided with an anode -64, a -control element 65 and shield grid 85 which is directly connected electrically with its-cathode 62. These elements of each of these valves are enclosed in an envelope which prefersupply circuit so that the electric valves 48 and 54 may be rendered conducting in response to the phase adjustable sine wave control voltage which determines the instant in each of the positive half cycles of anode voltage that these electric valves become conductive. This portion of the circuit hasbeen described and claimed in my copending application, Serial No. 685,330, for Electric valve control circuit, filed July 22, 1946, and assigned to the assignee of this application.

As illustrated in the drawing the control element circuit for each of the electric valves 40 and 54 branches into two parallel connected portions after passing through a current limiting resistor 67. One of the parallel portions includes in series with one another a unidirectional current conducting device 68, a secondary 69 of a transformer 10, and one of the winding portions H of the secondary 38 of transformer 39 between terminals 12, 42 and 13. The other parallel portion includes in series with one another a resistor 14 and a secondary 15 of a transformer 15. The control circuit for electric valve 40 is completed through uni-directional current conducting device 58 as follows: Conductor TI, device 68, conductor 18, winding 69, conductor 19, terminals l3 and 42 of winding 38 and conductor 81. The control circuit for electric valve 54 is completed through the other unidirectional conducting device as follows: Conductor 8!], device 68, conductor 8|, winding 69, conductor 82, terminals '12 and 42 of winding 38 and conductor M.

The unidirectional conducting device 68 polarizes the branch in which it is connected so that current may flow from the non-polarized branch through resistor 14 thereof, which will have a voltage drop corresponding to the difference in voltage of the secondary windings connected in these branch circuits when the resultant voltage is in a direction to cause the unidirectional current conducting device to conduct. The unidirectional current conducting device selectively and automatically impresses on the control element of the electric valves 4|] and 54 with which it is associated, the voltage of that branch of the control element circuit which is more negative. These unidirectional current conducting devices 68 may be electric discharge devices of the vacuum type having their anodes connected toward the control elements 65 of electric valves 40 and 54 and between resistors 61 and 14 in the control element circuits of these valves.

The secondary windings 15 of transformers 76 impress on control elements 65 of electric valves and 54 sine wave voltages of the same frequency as the supply circuit and adjustable in phase relation with regard to the anode-cathode voltages of these electric valves. As will appear below,these adjustable phase sine wave voltages determine the instant in the half cycles of positive anode voltage that conduction is initiated by electric valves 50 and 54 and consequently when the load circuit electric valves 9 and 8 become conductive. They, therefore, consequently determine the amount of current transmitted to the welding transformer and the work connected in the load circuit.

This heat control is obtained by connecting the primary windings 83 of transformers it in parallel with one another, and through conductors 84 and 85 in series with a resistor 85 across the output terminals 81 and 88 of a static phase shift network comprising winding sections 89 of the primary of transformer 51 which are connected in series with one another and as a unit in parallel with. a series circuit through capacitor 90 and resistors '9! and 92 across supply conductors 3,.through conductors d5, 49, winding section 58 of transformer 5| and conductor 52. Both resistors 94 and 92 are adjustable, one resistor being adjusted for providing full heat, that is, adjusting the control voltages of windings T5 to render electric valves 40 and 5*? conducting at the power factor phase angle of the load and the other being adjustable to decrease the heat by causing the phase control voltage to fire electric valves 40 and 54 at an adjustable time later in the cycle than the power factor phase angle of the load current. A capacitor 93 may be connected across the primary windings 15 of transformers 16 to increase the impedance of the primary circuits of these transformers and compensate for the-exciting current supplied by the phase shift network thereto. This prevents the normally semicircular locus of the control voltage victor from being pulled in toward its point of rotation determined by tap 88 of the winding sections 89. The resistor 86 provides means for reducing the efiect of line voltage disturbances on the phase controlled voltages supplied by transformers 16.

The winding sections H of the secondary 38 of transformer 39 impress in the control element circuits of electric valves 69 and 54 negative sine wave bias voltages of the same frequency as the supply circuit which is connected'through transformer 39 to the anode-cathode circuits of these electric valves. That is, the voltages of these secondary winding sections are in phase opposition to the anode-cathode voltages of these valves. The negative bias voltage of winding sections H of transformer 39 is rendered ineffective by opposing thereto a turn-on voltage of substantially sine wave form which is of greater magnitude than the negative bias voltage. This turn-on voltage is provided by the secondary windings 69 of transformer T0 and is of the same frequency as that of supply circuit 3. This turn on voltage is obtained from an oscillating closed circuit including primary windings 9d and B5 of transformer T0 and a tuning capacitor 535.

Primary winding 94 of transformer if! is connected across terminals 36 and 42 of the primary 38 of transformer 39, through conductor 34, cur:- rent limiting resistor 91, the anode-cathode circuit of a turn-on electric valve 98 and conductor 4|. Primary winding 95 of transformer 10 is connected in like manner across terminals 36 and 42 of the secondary 38 of the transformer 39 through conductor 34, resistor 99, the anodecathode circuit of a timing electric valve I99, and conductor 4I. Electric valves 99 and I99 each comprise an anode IN, a cathode I92, a control element I93 and a shield grid I99 which is directly connected electrically with its cathode I92. These elements are also enclosed within an envelope which, as indicated by the dot, preferably contains an ionizable medium such as gas or a vapor.

When electric valve 98 is conducting, the priniary windings 94 and 95 of transformer 19 are connected in series with one another for additive polarity and when both electric valves 99 and I99 are conducting these primary windings are connected in parallel with one another for opposite polarity. When both electric valves 99 and I99 are conducting, windings 99 and 95 by opposing one another reduce the impedance of their circuits to zero or a very low value and consequently at that time, the current through these valves is limited primarily by the resistors 91 and 99 connected in circuit therewith. A resistor I95 connected across the primary winding 99 is provided to increase the current flow through electric valve 99 and thereby maintain its ionization and conductionuntil the current flow passes through zero even though its control element I93 becomes negative relative to its cathode before its current flow passes through zero.

As will appear below, electric valve 99 is first rendered conducting and, at a predetermined time later, electric valve I99 is rendered conducting. As it is desired to have both of these electric valves conducting at the same time, a resistor I99 connected in series circuit with capacitor 99 across the anodes I9! of electric valves 99 and I99 serves to prevent conduction of electric valve I99 from extinguishing electric valve 99 by impressing a negative voltage on its anode.

With the arrangement described, the oscillating circuit including primary windings 99 and 95 of transformer 19 in close circuit with capacitor 9B is set in oscillation and energized for half cycles of voltage so long as only electric valve 98 conducts. When electric valves 99 and I99 are conducting simultaneously capacitor 96 is short circuited and the primary windings 99 and 95 of transformer 19 are connected in parallel with one another for opposing polarity so that the circuit abruptly stops oscillating and no voltage is induced in the secondary winding 99 of transformer 19. Thus, secondary windings 99 impress in the control element circuits of electric valves 49 and 59 full cycles of alternating current which is substantially sinusoidal in shape, of the same frequency as the supply circuit and of greater magnitude than the sine wave bias voltage impressed in these control circuits by the secondary winding sections 1! of transformer 38.

To obtain full cycles of alternate current in the oscillating circuit just described, it is desirable to have turn-on electric valve 99 start conducting at the beginning of the half cycle of its positive anode voltage and to have timing electric valve I99 start conducting at the beginning of a half cycle of its positive anode voltage, a pro-adjustable time later. This is accomplished by making these valves conducting in trailing fashion in response to the conduction of a keying electric valve I91.

Electric valve I91 comprises an anode E99, a

cathode I99, a control grid H9, and a shield grid III which is directly connected electrically with its cathode I99. These elements are enclosed in an envelope which, as indicated by the dot, preferably contains an ionizable medium such as a gas or vapor. The anode-cathode circuit of this electric valve is connected in series with an inductive load comprising the primary winding I I2 of a control transformer I I3 and the parallel connected resistor II4 across the terminals 92, 59 of the secondary 38 of transformer 99. It will be noted that the cathodes I92 of electric valves 99 and I99 and the cathode I99 of electric valve 391 are directly connected together and to terminal 92 of the secondary 38 of transformer 99. It will also be noted that the anodes I9! of electric valves 99 and I99 are connected to the potential of terminal 36 of winding 38 of transformer 39 whereas the anode I98 of electric valve I91 is connected to terminal 59 of this primary winding 39. Thus, electric valves 99 and I99 may become conducting during a half cycle of supply circuit 3 when their anodes are positive and electric circuit I91 may become conducting during the next half cycle of the supply circuit 9 when its anode becomes positive. Since, as will he pointed out below, conduction of electric valves 99 and I99 is dependent on electric valve I91 it may be stated that electric valves 93 and I99 conduct in trailing response to the conductivity of electric valve I91.

As previously noted, the cathodes of electric valves 98, I99, and I91 are directly connected together by conductor 4I. Conduction of electric valve 99 is made dependent on conduction of electric valve I91 by connecting its control element I93 through current limiting resistor I I9, a negative self-biasing means comprising parallel connected capacitor I I9 and resistor I I1 and conductor II 8 to the anode connection of electric valve I91 with the inductive device II2, IE9.

Electric valve I91 is a rectifier and passes current in one direction only, but due to its inductive load H2, H4, it continues to conduct over and into the next half cycle of supply voltage for about 15 thereof, while part of the stored energy in its inductive load is fed back to the suppiy circuit. Thus, when electric valve I91 is conducting, its anode voltage drop causes electric valve 99 to trail in conduction during the negative half cycle of electric valve I91 which corresponds to the next positive half cycle of anode voltage for electric valve 99. The control potential thus obtained for electric valve 98 has a substantially rectangular wave form and is of practically constant magnitude as limited by the drop across electric valve I91. This voltage drop will usually be about 15 volts for gas valves of the type usually used. It will be noted that when electric valve I91 is nonconducting, the voltage across it is in phase opposition to the anodecathode voltage of electric valve 98 and that this voltage applied in the control circuit of electric valve 98 holds it nonconducting.

The conductivity of electric valve I99 is also made dependent on the conductivity of electric valve I91 by connecting their cathodes together through conductor 4| and by connecting the control element I93 of electric valve Hi9 to the anode connection of electric valve I91 through a current limiting resistor H9, a timing capacitor 529, a resistor IZI and conductor I it. During the time that electric valve I91 does not conduct, capacitor I29 is chargedthrough a hot cathode rectifier I22 which may be of the vacuum type aas n s is gnne t d ficu wi th cams? e ase c ee res t es a ve s valve is connected 'i'nseries with its voltage abso hing resistor l2'l across the anode and cathode te nals l tric a ve'l i- Valve. 3 ay e s terated o the attain discharge ty e wh ch when co u tin ma n ai a es. in erminal a s tan al cen ta t volta e a different va ue f current 110 th ret eush- Th P t c la va ve emnl is r gu ted o F it? Wi ts r s ts. ermina Ez-leet i va v w l not c nd ct the e e evenafter electric valve Ill! becomes conductin until the charge on capaciti r L213 has decreased through it adjustable discharge circuit 124. Th s di har e Qi l iti l l d t fi ed e te sas a adiu tab res st A l ustr ed e s c the fi ed resi te sm he s q t cir ed a range switch in order to remove it from the disc ar s e i- Th ad ustab is h r e circu t 124 h capes tat it i qm d t rc ss the diustah e P .35??? fi uhi on e ted n se e v sisto '16 ar e t th termina s. of the vol e regulating valve i131. Since a voltage wea across-th volta re u ating valve n it rev rs d ection, resistor .125 and potentiQl lfill r i255 perate touforce the voltage of capacitor. [2-0, down at an accellerated rate. during the negative half cycle of anode voltage of electrio valve 101. The arrangement is such that timing electric valve lllfl becomes conducting atthe beginning of a positive half cycle that occurs a full number otcycles later than the time turnron electric valve 98 starts conducting. The adjustable resistor in thevdischarge circuit 12 maybe tapped. to provideone cycle timing increments .and'with the proper adjustment of potentiometer I the full number or cycles will invariably be the same. This insures timing of the main orv powerl valves for: conduction i-n the full cycle steps. In each case, electric valves 98 and 10!! trail keying electric valve 101 inresponse. to the trailing. component of control element voltage from its anode I08 which results from its conducting-over into the negative half cycle which corresponds to the positive half cycle or electric valves 98 and H10.

I he hot cathode rectifier L22 provided for charging. capacitor 4-21) is used instead ofthe grid-cathode circuit ot'electric valve I 00 in acco -dance with the disclosure in my above referred to application Serial No. 685,330, because for long timing intervals, it is necessary to use a larger capacitor and this capacitor must be charged quickly at a comparatively high current rate. The reason for using a largercapacitor is s that the resistance of the discharge circuit is not made so great that the discharge through stray circuits seriously afiects itstirning function.

Hot cathode rectifiers have, however, a selfgenerated voltage which will apply to a capacitor in circuit therewith, a charge which will interiere with itsaccurat timing which of course is dependent on the capacitor-receiving; only a predetermined charge. Th circuit through the capacitor and rectifier to which this salts-generated voltage is applied maybe circuitous and indirect or maybe completedby leakage between conductors connected in circuit with the rectifier and capacitor; In the arrangement illustrated, this. self generated voltage is neutralized or overcome by the voltage of. the secondary I21 of. the filamentheating transformer |28-for rectifier I22 The primary winding T29 cf transformer 128 is connected through conductors I30 across the lower primary winding section 89 of transformer 5| so that the terminal of the secondary $21 of this transformer which is connected to the cathode ofrectiiier 122, is at a positive polarity relative to the cathode H32 of electric valve Hill when a positive anode potential-is applied to rectifier l22j This polarity, ifof sufficient magnitude, will not only neutralize the self generated voltage of rectifier 122 but will also positively determine the voltage of terminal l3l of capacitor 120, which is connected to the control element [03 of electric valve we, relative to the cathode potential of this electric valve. Thus, the circuit arransement provided will 1 always insure that capacitor 128 can discharge to a value such that a positive firing potential-may be applied to the control element [-03 of electric valve I by the voltage drop across electric-valve 191. This operation is insured by making the hot cathode rectifier 22 of the controlled type and connecting its control'element I32! through a long time constant negative self-biasing means comprising parallel connected resistor I33 and capacitor I34, a resistor and conductor 60 to terminal 6] of the secondary winding 3 8 of; transformer 39 so that this rectifier becomes conducting only during the middle portion of its positive anode voltage when th voltage of secondary winding 121 is at or above the desired value.

Keying electric valve I01 is normally held nonconductin by applying; to its control element l lo an alternating voltage that-is degrees out of phase with its anode voltage, This voltage. is applied through a control circuit comprising conductor 4!, the winding portion between taps i2 and 35 of thesecondary 38 oftrans-former 39, conductor 3'4, resistor I36, conductor 1 31,

negative salt-biasing means 138,;and a current limiting resistor I 39.

Electric valve 1131 is rendered conducting by the closure oi a push-button switch i140. When this. w tch. s cl sed the n e H0. of

7 electric valve lq'l is connected across capacitor t ll of a phase shift Circuit including this capacit and a resi r 4; onne t a o o ductors iii and 34 totaps 42; and 36 of" the secondcr .8. o transiorme 9 he r an ement is s ch t a w th. swi ch 0 o d. a volta e eadi the anode-cathodev voltage oi electric valve it! by l h ly. l ss han 1.8. de rees i ar to t le ent c ements; th s l ct. rvahet j render t qnductinsd rins t e. first e e re its nos t v anqde. vo t e- Ellectric valve Jill; may be rendered periodically c nd c ing a noncondu ns to s b i h p determined time-on and time-offperiods by means of an initiating electric valve M3 which is connected to become operating when the threeladed switch MA-is moved fromthe positionillushated to a position completing circuits through conductors M5, [46 and I 41. The circuitscomplated through conductor M5 connect the anodecathode circuit of initiating electric valve M3 in parallel with the anode-cathode circuit of turn on electric valve l-9-8. It also connects the anodes of these electric valves through conductors I45, I46 and I31 negative self-biasing means l35- and resistor I39, to the-control-element H0 ofelectric valve NH: so as to cause this electric valve to. trail the operation of either electric valves I43 or 98 in the same manner as electric valve 98 operates in trailing fashion depending upon theoperation of: electric valve llt'lr. Thus,

once the initiating electric valve I43 is rendered conducting, keying electric valve I01 will become conducting and thereafter electric valves 98 and I51 will become alternately conducting until finally both electric valves 98 and I become conducting when the inductance through 98 becomes zero resulting from the windings 94 and 95 of transformer opposing one another, as ha been previously described.

With the three-bladed switch I44 in the off position illustrated, initiating electric valve I43 is held nonconducting by the bias applied to one of its control elements through resistor I48, left blade of switch IM, conductor I49, potentiometer resistor I55 and conductors I5I and 4|. Potentiometer resistor I is connected in series with another resistor I52 across a source of direct current potential I53. This potential is derived from the alternating current supply circuit-3 through a full-wave rectifier I54 energized from the supply circuit 3 through transformer 5|. This rectifier comprises a double anode discharge device I55 having a resistor I56 connected in series with its output circuit I53 and a capacitor I51 connected thereacross in order to stabilize the direct current voltage obtained from' the source 5 through the rectifier I54. The voltage across the potentiometer I50, I52 is further stabilized and maintained at a substantially constant value by a voltage regulating valve I58. This valve is connected in series across the direct current source I53 through a voltage absorbing resistor I59. Electric valve I58 may be, as indicated, of the gaseous discharge type which, when conducting, maintains across its terminals a substantially constant voltage for different values of current flow therethrough.

Provision is also made for charging a timing capacitor I 50 through a controlled rectifier I6I from the source of supply I 53. Capacitor I has permanently connected thereacross a discharge circuit I62.

Capacitor I50 is charged from the direct current source I53 whenever electric valve I6I becomes conducting. Its period of conductivity is made dependent upon the conductivity of electric valve I01 by connecting its control element I53 through a current limiting resistor I64, secondary winding I55 of control transformer H3, resistor I55 and conductor I49 to its cathode. The voltage drop across resistor I59 normally applies a negative potential to control element .I53 so that electric valve I6I is held nonconduoting until this negative bias potential is overcome by the voltage induced in the secondary winding I55 of control transformer H3 in response to current flow through the primary winding II2 of this transformer at the time electric valve I01 is conducting.

Electric valve I43 is provided with two control elements I56 and I61. Control element I66 is connected in the circuit previously described whereby the negative hold-off value of voltage across resistor I50 is applied thereto so long as switch I44 is in its off position as illustrated. When the switch I44 is thrown to its on position, control element I66 is connected through" resistor I58 to the negative terminal of capacitor I50 through this capacitor and resistor I52 and conductors I5! and 4| to its cathode. Assuming that capacitor I50 is uncharged, electric valve I43 has applied to its control-element I66 the positive voltage across resistor I52 and will conduct when its anode is positive provided apositive control value of voltage is applied to its controlelement I61. Control element I61 is connected through a conductor I58 to a phase shift circuit comprising a capacitor I59 and a resistor I10, which is like the phase shift circuit previously described for electric valve I01 as comprising capacitor I 4I and resistor I42. Consequently, the alternating current control potential applied to control element I51 leads the anode potential of electric valve I40 by something less than degrees so that this valve becomes conducting only at the beginning of a positive half-cycle of its anode voltage.

Capacitor I50 times the ofi period between periods of conduction determined by capacitor I20 previously described as to function and circuits of which it forms a part. If capacitor I60 is charged, electric valve I 43 does not become conducting until its discharge circuit I 62 has reduced its voltage to a predetermined value.

Capacitors III are connected across the control'elements and cathodes of electric valves I3, It, 40, 5t, 98, I00, I01 and I43 to render these valves resistant to faulty operation resulting from transient anode voltages applied thereto. Except for the hot cathode rectifier I22, the heating means and circuit therefor for each of the other electric valves have not been illustrated, in order to simplify the drawing. It is to be un derstood, however, that the heating filaments are connected with the source of supply 3 through transformers energized from this source in a manner similar to the illustrated arrangement for applying heating current to the filament of rectifier I22 through filament heating transformer I28. It will be noted that with such an arrangement the cathode heating circuits for the several electric valves will be in operation as soon as the line switches 1 are closed to energize the supply circuit 3 from the source of supply 2. Anode-cathode potential will not, however, be applied to these valves until contacts 44 of time delay relay 45 have closed. The operating coil I12 of this relay is connected across the lower winding section 59 of the primary winding of transformer 5i. After a predetermined time interval determined by relay 45, this relay will close its contacts 44 thereby connecting the primary 43 of transformer 39 to the supply circuit 3 and thereby applying anode potential to the electric valves connected to the secondary winding of this transformer. If the operator then closes the weld switch I13, operating winding I14 of relay 2| will be energized by being connected across the terminals 42 and 55 of the secondary 38 of transformer 39 through conductors M and 59. When this relay closes its contacts 20, the anode.- cathode circuits through the firing electric valves I3 and I4 will be completed and the system will be in condition for operation.

A voltage limiting means I15 may also be connected across the primary winding of the welding transformer 5 to protect it from voltage surges. This means has been illustrated as a. resistor and may be of the type described and clamed in U. S. Letters Patent 1,822,742, Karl B. McEachron, September 8, 1931.

The features and advantages of the system of Figs. 1a. and 1b will be better understood from the following description of its operation.

In order to condition the system for operation, hand switches 1 are closed to connect the supply circuit 3 with the source of alternating current 2. Upon closure of switches 1, the various heating circuits for the hot cathode electric valves will be energized and, after a predetermined time delay,

phase shift circuit anode potential will be applied. to. thoseelectric valves having their anode-cathode circuits con.- Iiectedwith the secondary winding 38: of. transformer39. Thereafter, when the operator closes the weld switch I13, relay 2| will close its contacts to complete the anode-cathode circuits of electric valves I3 and I4, which are the firing valvesfor the main electric valves 8 and 9 which are reversely connected in parallel between. the load circuit and the supply circuit for: supplying alternating current to the load circuit.

The load circuit may be energized at will for single periods of predetermined adjustable. length byclosing push button I40 or it may be automatically energized intermittently by closing switch M4. The period of energization is'determined by'timing capacitor I20, and. duringrinterr nittent operation, the interval between periods of energization is determined by the timingcapacitor I60.

Initially, the main'or load circuit electric valves 8" and 9, their firing electric valves I3 and I4, relay valves 40 and 54, turn-on electric valve 98, timing electric valve I and keying electric valve I01 are all nonconducting.

Relay electric valves 40 and 54 are held; nonconducting by the imposition on their control elements 65 of the-more negative of. the phase shift controlvoltages of secondaries I of'transformers TE or the negative bias voltages of windingzsections 'II- of the secondary 38 of transformer 39. The more negative of these voltages. is selectively and automatically applied to the control elements 65"by'means of the unidirectional conductin devices 68, as pointed out in greater detail above.

When-the operator closes the push button I40, keying electric valve I0! is rendered conducting at" the beginning of a half cycle of its positive anode voltage in response to the voltage of the MI, I42, which, as previously stated leads the anode voltage of electric valve I01 by slightly less than 180 degrees. Previous to the closureof switch I40, electric valve 101' was held nonconductin by the out-of-phase voltage applied to its control element by reason of the connection of its control circuit across. terminals 2, 36 of the secondary 38 of transformer 39 which supplies a voltage out of phase with the anode voltage applied to this electric valve I01 by-reason of its connection across terminals 56,

#2: of the secondary 38' of transformer 39'.

When electric valve I01 becomes conducting,

the trailing voltage drop thereacross renders turn-on' electric valve 98 conducting. While electric valve I 0-? was nonconducting, the voltage across its anode and cathode which is out of phase with the anode-cathode voltage of electric valve 98 was applied to the control element I03 of electric valve 93" and held it nonconducting. When electric valve 58 becomes conducting, it connects the primary winding 90 of transformer across terminals 38 and 42 of the secondary of transformer 39 and therebyenergizesthe oscillating circuit, comprising primary windings 94' and 95 of transformer I0 and the capacitor 96 connected in circuit therewith. As soon as this circuit is set in oscillation, the secondaries 69' of transformer 10 apply control voltages to the control element circuits of electric valves and 54 which overcome the negative bias voltages of) the secondary 3B of transformer 39-and permit electric valves 40 and 5G to become conducting atthe phase angledetermined by the adjustment of; the static phase shift circuit across the output terminals 81 and 88- of which the primarywind ingsl 83r of control transformers 1B are connected.

ti'on of theprimaries: 32 and 5'! of control transformers 25 and 3| with thesecondary winding 38= of transformer 39. This produces a. corresponding reversal of. the phase of the voltage.- in thesecondaries 25 and30 of these control transformers 26 and 3|, which causes electric. valves M and: L3; to become conducting in response to the steep wave front of voltage resulting from the. reversal in phase of the. voltage Sincethis reversal: inthe phase. voltage occurs at thepower factor: phasevan'gle-of the load or at some later time: dependingv on: the adjustment of resistors 9 Iv andr92 or the static phase shift circuit, the voltagesapplied to the control element ll of electric valves I37 and It abruptly change froma negative valueofsubstantial. magnitude to a corresponding' positive value of the same magnitude, This insures balanced operation of the load circuit electric valves 8 and 9 and their firingelectric valves I3 and I4 irrespective of. variations in the critical. control characteristics of these electric valvesrand irrespective of any abrupt change in their. cathode potentials.

Keying. electric valve I01 continues to conduct during; its positive hali cycles-of anode voltage so long as push button 140 is maintained closed;;and turn-.011 electric valve 98 conducts in trailing. response tothe lagging voltage drop across electric valve Hl'l until timing electric valve Iililconductsand connects primary winding Blito transformer 10 across terminals 3'6, 42* of thesecondary 38;of transformer 30. Whenelectrio-valves 98' and; I00 are conducting simultaneously, capacitor is short circuitecl and the primary windings Standfifi of the transformerlh are connected; inparallel with one another-for opposing polarity so that the oscillating: circuit of whichthey form a part abruptly stops oscillating and no voltage is induced; inthe secondary: winding; 69 of transformer 10;. The more negative" of the control voltages derived from-secondaries'l 5- oftransformers. 16 or winding sections l Ii ofi thesecond'ary 38 of transformer 39 thereafterhold electric:- valves 50 and: '54- nonconducting.

Timing. electric: valve; 100 is rendered. conductg afullnumber of. half cycles after electric valve 93 was rendered conducting by the timing efiecthof capacitor I20. This: capacitor was charged up through its hot cathode rectifier 22during the time that electric valve. Ill] was nonconducting prior to the closure of push button MEI. Thereafter when electric valve I01 was conducting while push button. M0 was. closed, the charge on this capacitor leaked ofi through its discharge circuit I24 until lagging voltage drop across electric valve I01 was sufiicient torender electric'valve I00 conducting at the beginning of a positive half cycle of its anode voltage This operation was insured by the fact that the voltage of' the secondary winding I01 of the filament heating transformer was so connected in. the charging circuit ofcapacitor I 20. as to oppose the self -generated voltage of the hot. cathode rectifler I 22'and at the same-time insurethat the control element connection. I3I of capacitor I20 was 15. hex-obtained; by opening; the push-button switch [7 I48 and thereafter closing it again. While the push-button switch I48 is open, capacitor I28 is charged by reason of its connection across the terminals 56 and 42 of the secondary 38 of transformer 39.

For automatic intermittent energization of the load circuit in which each period of energization is accurately timed by capacitor I28 and the interval between energizations is timed by capacitor I68, the operator closes the switch M4 from the ofi position illustrated to the position in which circuits are completed through conductors I45, I46 and I41.

If electric valve I81 has not previously been conducting, capacitor I 88 is not charged and consequently the completion of the circuit through conductor I81 applies a positive control voltage to the control element I66 of initiating electric valve I 33. This electric valve will not become conducting, however, until a positive control voltage is also applied to its second control element I61 by reason of its connection I88 with the phase shift circuit I89, H8. This phase shift circuit, as the previously described circuit MI, 12 for electric valve I81, applies a positive control voltage to control element I 61 of electric valve I43 only during the first few degrees of a positive half cycle of voltage applied to the anode of electric valve I43.

It will be noted that the anode-cathode circuit of electric valve I43 is connected in parallel with the anode-cathode circuit of electric valve 98 through conductors I85 and 4!. Consequently, when electric valve M3 becomes conducting it energizes the' primary winding 98 of transformer I8 and initiates the period during which the load is energized for the reasons above given in connection with the operation above described as resulting from the closure of push button I48.

It will be noted that the anodes of electric valves M3 and 98 areconnected through conductors I45 and I it to-the control element I I8 of electric valve I81 so that this electric valve I81 will become conducting in trailing response to the lagging voltage drop across either of electric valves Hi3 or 98. Consequently, when electric valve I83 became conducting, electric valve I81 became conducting and thereafter electricvalves 98 and I81 became alternately conducting until the flow of lagging current through electric valve 98 disappears at the time eiectric valve I88 becomes conducting and reduces to zero or a very low value the inductance of the circuit through electric valve 98.

Once electric valve Iil'i became conducting, control potential was applied to control element I83 valve #33 again becomes conducting to initiate another period of energization of the load circuit.

It is thus apparent that with the control system illustrated, independent energizations of thev load circuit may be had at the will of the operator by closing push button I48 and maintaining it closed until the end of an energization period, or that automatic repeated energizations of the load circuit with full electronic timing of the periods on and ed may be had by closing switch I44. In either case, the arrangement is such that full cycles of welding current are supplied to the load circuit and the amount of load current may be adjusted by an adjustment of a phase shift circuit which controls the point in the half cycle of voltage at which the electric valves become conducting.

Gaseous electric valves, such as the timing electric valve I88, have a small negative grid current flow characteristic. Consequently, the connection of the timing capacitor I28 across the circuit completed between the cathode and grid of such an electric valve will furnish an additional discharge circuit for the capacitor which will make it necessary to adjust the discharge circuit I24 of the capacitor unequal amounts for integral multiples of the discharge periods of the capacitor. It is desirable to have equal adjustments of the resistor in discharge circuit I24 produce equal timing periods, and this may be accomplished by using the modification shown in Fig. 2 of the drawings.

In Fig. 2 of the drawings, the same portions of the circuit shown in Fig. 1a have been identified by the same reference numerals. It will be noted, however, that the control element I83 of electric valve I88 is connected with terminal I3I of capacitor I28 through a cathode follower circuit including electric valve I16 and cathode follower resistor I11, which are connected in circuit with one another, and conductors I18 and I19 across conductors 82 and 19, which in turn are connected to terminals 12 and 18 of the secondary 38 of transformer 39. Electric valve I16 is of the vacuum type and has no sensible negative grid current flow. Its grid or control element I88 is connected through a current limiting resistor I8I to terminal I3I of capacitor I28, and its cathode I82 is connected through current limiting resistor IIII to control element I83 of the electric valve I88 which, as indicated, is of the gas type and has a negative grid current flow characteristic. With such an arrangement, discharge of capacitor I I28 except through its discharge circuit is effectively prohibited and equal adjustments of the adjustable resistor in the discharge circuit I24 will produce equal timing intervals for capacitor I28.

It is, of course, apparent that my invention is not limited in its application to the use of electric -plying a steep wave front of control voltage in order to insure balanced firing of the load circuit valves may be used with the desirable advantages characteristic of the system above described. It

is also apparent that where it is necessary only to supply to the load circuit a half cycle or less of supply circuit current, a single electric valve may be used and the uniformity of its current conduction periods resulting from the steep wave front of voltage applied thereto will be of great advantage in obtaining uniform time intervals of current flow irrespective of variations in the critical control characteristics of the electric valve resulting from structural variations therein or by reason of its particular connection in the, load circuit producing transient cathode potentials which interfere with such accurate timing.

Therefore, while I have shown and described a particular embodiment of my invention and a variation thereof, it will be obvious to those skilled in the art that the above changes, as well as many others, may be made without departing from my invention in its broader aspects, and I therefore aim in the appended claims to cover all such changes and modifications as fall Within the true spirit and scope of my invention.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. Apparatus comprising an alternating current supply circuit, two electric valves each of which has an anode, a cathode, and a control element, a direct connection between the cathodes of said electric valves, means for connecting the anode-cathode circuits of said electric valves for energization from said supply circuit with the anode voltage of one of said electric valves at a voltage of said supply circuit which is of one polarity when the anode voltage of the other of said electric valves is at a voltage of said supply circuit which is of the opposite polarity so that one of said electric valves may conduct during half cycles -of voltage of one polarity and the other of said valves may conduct during half cycles of voltage of the opposite polarity, said means providing inductive circuits through the anode-cathode circuits of each of said electric valves, means for introducing into the control element circuit of one of said electric valves a voltage rendering said one of said electric valves conducting, and means for connecting each of said electric valves for operation in trailing respouse to the other of said electric valves, said means including for each of said electric valves control element circuits which are completed through the anode-cathode circuit of the other of said electric valves and which apply to the control element of each or said electric valves the trailing voltage drop across the anode and cathode of the other of said electric valves resulting from conduction through said other electric valve continuing over into its negative half cycle of anode voltage which corresponds to the positive half cycle of anode voltage of the electric valve next operating in trailing sequence.

2. Apparatus comprising an alternating current supply circuit, two electric valves each of which has an anode, a cathode, a control ele-- ment, and a control element circuit, a direct connection between the cathodes of said electric valves, means for connecting the anode-cathode circuits of said electric valves for energization from said supply circuit with the anode voltage of one of said electric valves at a voltage of said supply circuit which is of one polarity when the anode voltage of the other of said electric valves is at a voltage of said suppl circuit which is of *e opposite polarity so that one of said electric valves may conduct during half cycles of volt age of one polarity and the other of said valves may conduct during half cycles of voltage of the opposite polarity, said means providing an inductive circuit through the anode-cathode connection of each of said electric valves with said sul ply circuit, means for connecting the control element circuits of each of said electric valves in circuit with the trailing voltage drop appeari'ng across the other of said electric valves as a result of current flow through each of said electric valves continuing over into its negative half cycle of its anode voltage which corresponds to the positive half cycle of anode voltage of the other of said electric valves and thereby causing said electric valves to conduct alternately in trailing response to one another, and means for introducing into the control element circuit of one of said electric valves a voltage rendering said one of said valves initially conductive.

3. Apparatus comprising two electric valves each of which has an anode, a cathode, and a control element, a direct connection between the cathodes of said electric valves, an alternating current supply circuit, means for connecting the anode-cathode circuits of said electric valves for energization from said supply circuit with the anode voltage of one of said electric valves at a voltage of said supply circuit which is of one polarity when the anode voltage of the other of said electric valves is at a voltage of said supply circuit which is of the opposite polarity so that one of said electric valves may conduct during half cycles of voltage of one polarity and the other of said valves may conduct during half cycles of voltage of the opposite polarity, said means providing an inductive circuit through the anode-cathode connection of each of said electric valves with said supply circuit, means for connecting the control elements of each of said electric valves to be responsive to the voltage of said supply circuit appearing across the anode and cathode of the other of said electric valves, and means for initiating conduction for one said electric valve and thereby thealter'nate conduction of both of said electric valves in response to the trailing voltage drop appearing across each of said electric valves as a result of the laggin current flow therethrough.

4. Apparatus comprising two electric valves each of which has an anode, a cathode, and a control element, a direct connection between the cathodes of said electric valves, an alternating current supply circuit, means for connecting the anode-cathode circuits of said electric valves for energization from said supply circuit with the anode voltage of one of said electric valves at a voltage of said supply circuit which is of one polarity when the anode voltage of the other'of said electric valves is at a voltage of said supply circuit which is of the opposite polarity so that one of said electric valves may conduct during half cycles of voltage of one polarity and the other of said valves may conduct during half cycles of voltage of the opposite polarity, said means providing an inductive circuit through the anode-cathode connection of each of said electric valves with said supply circuit, means for connecting the control elements of each of said electric valves to be responsive to the voltage of said su ply circu t a pearin across the anode and cathode of the other of said electric valves, means for initiating conduction of one said electric valve and thereby the alternate conduction of both of said electric valvesin response to the trailing voltage drop appearing across each of said electric valves as a result of the logging current flow therethrough, and means for interrupting the trailing operation of said pair of electric valves.

'5. Apparatus comprising two electric valves each of which has an anode, a cathode, and a control element, a direct connection between the cathodes of said electric valves, an alternating current supply circuit, means for supplying connecting the anode-cathode circuits of said electric valves for energization from said supply circuit with the anode voltage of one of said electric valves at a voltage of said supply circuit which is of one polarity when the anode voltage of the other of said electric valves is at a voltage of said supply circuit which is of the opposite polarity so that one of said electric valves may conduct during half cycles of voltage of one polarity and the other of said electric valves may conduct during half cycles of voltage of the opposite polarity, said means providing an inductive circuit through the anode-cathode connection of each of said electric valves with said supply circuit, means for connecting the control elements of each of said electric valves to be responsive to the voltage of said supply circuit appearing across the anode and cathode of the other of said electric valves, means for initiating conduction of one said electric valve and thereby the alternate conduction of both of said electric valves in response to the trailing voltage drop appearing across each of said electric valves as a result of the lagging current flow therethrough, and means for eliminating the lag ing current flow through one of said electric valves and thereby interrupting the trailing operation of said pair of electric valves.

6. Apparatus comprising an alternating current supply circuit, a pair of electric valves each of which has an anode, a cathode, and a control element, means connecting the c thodes of said electric valves to the same potential of said alternating current supply circuit and the anodes of said electric valves to potentials of said supply circuit such that one of said electric valves may conduct durin half cycles of voltage of one polarity and the other of said electric valves may conduct during half cycles of voltage of the opposite polarity, said means providing an inductive circuit through each of said pair of electric valves so that the current flow therethrough lags its positive anode voltage, mean for connecting the control elements of each of said electric valves in circuit with the trailin voltage drop across the anode-cathode circuit of the other of said electric valves so that each of said pair of electric valves conducts in trailing response to the other. a third electric valve having an anode, a cathode and a control element and having its anode-cathode circuit connected in parallel with the anode-cathode circuit of one of said pair of electric valves for establishing conduction through said inductive circuit of said one electric valve in the same direction as said one electric valve, means for applyin a control potential to the control element of said third electric valve to render it conductive and thereby initiating operation of said pair of electric valves which thereafter become conductive alternatively each in trailing response to the other, and timing means initiated in response to the initiation of conduction through one of said pair of electric valves and eiTective after a predetermined time delay for interrupting the trailing operation of said pair of electric valves.

7 7. Apparatus comprising an alternating current supply circuit, a pair of electric valves each of which has an anode, a, cathode, and a control element, means connecting the cathodes of said electric valves to the same potential of said alternating current supply circuit and the anodes of said electric valves to potentials of said supply circuit such that one of said electric valves may conduct during half cycles of voltage of one polarity and the other of said Y electric valves may conduct during half cycles of voltage of the opposite polarity, said means providing an inductive circuit through each of said pair of electric valves so that the current flow therethrough lags its positive anode voltage, means for connecting the control elements of each of said electric valves in circuit with the trailing voltage drop across the anode-cathode circuit of the other of said electric valves so that each of said pair of electric valves conducts in trailing response to the other, a third electric valve having an anode, a cathode, and a control element and having its anode-cathode circuit connected in parallel with the anodecathode circuit of one of said pair of electric valves for establishing conduction through said inductive circuit of said one electric valve in the same direction as said one electric valve, means for applying a control potential to the control element of said third electric valve to render it conductive and thereby initiating operation of said pair of electric valves which thereafter become conductive alternatively each in trailing response to the other, and timing means initiated in response to the initiation of conduction through one of said pair of electric valves and effective after a predetermined time delay for eliminating the lagging current through one of said pair of electric valves and thereby breaking the alternate sequential operation of said pair of electric valves in trailing response to one another.

8. Apparatus comprising an alternating current supply circuit, a pair of electric valves each of which has an anode, a cathode, and a control element, means connecting the cathodes of said electric valves to the same potential of said alternating current supply circuit and the anodes of said electric valves to potentials of said supply circuit such that one of said electric valves may conduct during half cycles of voltage of one polarity and. the other of. said electric valves may conduct during half cycles of voltage of the opposite polarity, said means providing an inductive circuit through each of said pair of electric valves so that the current flow therethrough lags its positive anode voltage, means for connecting the control elements of each of said electric valves in circuit with the trailin voltage drop across the anode-cathodecircuit of the other of said electric valves so that each of said pair of electric valves conducts in trailing response to the other, a third electric valve having an anode, a cathode, and a control element and having its anode-cathode circuit connected in parallel with the anodecathode circuit of one of said pair of electric valves for establishing conduction through said inductive circuit of said one electric valve in the same direction as said one electric valve, means for applying a control potential to the control element of said third electric valve to render it conductive and thereby initiating operation of said pair of electric valves which thereafter become conductive alternatively each in trailing response to the other, and timing means initiated in response to the initiation of conduction through one of said pair of electric valves and effective after a predetermined time delay for connecting one of said, electric valves with said supply circuit through a noninductive circuit and thereby eliminating the trailing voltage drop due to current flow through said one of said electric valves.

9. Apparatus comprising an alternating current supply circuit, a pair of electric valves each of which has an anode, a cathode, and a control element, means connecting the cathodes of said electrio valves tothe same: otential of said: Supply circuit and the anodes or said electric valves to potentials of said' simply circuits-such that one of: said electric valves may conduct during half cycles of" voltage of one polarity and the other of said electric valves may conduct during half cycles of voltage. of the opposite polarity, said means comprising an inductive circuit through each of said pair of electric valves whereby lagging current flows through the anode-cathode circuits of said electric valves, means for'connecting the control elements of each of said electricvalves in circuit with the trailing voltage drop across the anodecathode circuit of the other of said electric valves so that said pair of electric valves conduct alternately'in trailing response to one another, means including a capacitor for timing the operating period of said pair of electric valves, means including a second. capacitor for timing the nonoperating period of said pair of electric valves, charging and discharging circuits for each of said capacitors, means responsive to the conductivity of one of said pairs of electric valves'for initiating the discharging of said first mentioned capacitor and the charging of said second capacitor and responsive to. the non-conductivity of said one of said pairs of electric valves for initiating the. charging of said first mentioned capacitor and the discharging of said second. capacitor, means for initiating conduction of one of said pairs of electric valves, meansresponsive to the discharging of. said first mentioned capacitor to a predeter mined value for interrupting the trailing operation of said pair of electric valves, and means responsive to the discharge of said second capacitor for again initiating the operation of said pair of'electric valves.

10. Apparatus comprising an alternating current supply circuit, a control transformer having primary and secondary windings, an electric valve for connectingthe primary winding of said transformer for energization fromsaid alternating current supply circuit, said electric valve having an anode, a cathode and a control element, means for applying control potentials to the control element of said electric valve to render it conducting and after a predetermined time. delay nonconducting, a capacitor, a discharge circuit continually effective for discharging said capacitor at a predetermined rate, direct current supply conductors, means including a second electric valve for connecting said capacitor in a charging circuit across said direct current supply conductors, said second electric valve having an anode, a cathode and a control element, means for rendering said second electric valve conducting in response to the conductivity of said first mentioned electric valve, said means including a control element circuit for' said second electric valve having connected therein the secondary winding of said control transformer, and means responsive to the voltage or said capacitor for again rendering said first mentioned electric valve conducting after a predetermined delay depending on the discharge rate of said capacitor.

11. Apparatus comprising an alternating current supply circuit, a contro transformer having primary and secondary windings, a pair of electric valves, one of which has an anode, a cathode and a control element, and the other of which has an anode, a cathode and a pair of control elements, means for supplying alternating voltages of said simply circuit to said electric valves so that one of. said electric valves may conduct during half cycles or. voltage or one polarity and the other of said valves may conduct during half cycles of voltage of the opposite polarity, said means pro viding an inductive circuit through the anodecathode connection of each of said electric valves with said alternating voltage and the inductivecircuit through said one of said electric valves including the primary winding of said controltransformer, means for connecting the controlelement of said one of said electric valves to be responsive to the voltage of said supply circuit appearing across the anode and cathode of said other electric valve and for connecting one of the control elements of. said other electric valve to a potential of said supply circuit that renders said electric valve conducting during a positive half cycle of the anode voltage of said other electric va1ve providing the potential applied to its second control element will permit said second electric valve to become conducting, direct current supply conductors, a capacitor, means including a third electric valve. for charging said capacitor from said direct current supply conductors, said elec' tric valve having: an anode, a cathode and acontrol element, means continually effective for discharging said capacitor at' a predetermined rate, a potentiometer having a mid-tap'and having its outside terminals connected across said direct cur-' rent supply conductors, means for connecting the cathode of said other electric valve to said mid-tap of said potentiometer, means for sele'c tively connecting the second control element of said other electric valve to the negative terminal of said capacitor or the negative conductor 01'. said direct current supply conductors, means for applying a negative bias potential to the control element of said third electric valve, means he sponsive to the current flow through the anodecathode circuit of said one electric valve for applying a control potential to the control element of said third electric valve which overcomes said bias potential and renders said third electric valve conducting, and means for maintaining said one electric valve conducting for a predetermined period of time, after which said valve becomes nonconducting until' said capacitor discharges to a voltage which again renders said other electric valve conducting and said one electric valve again conducting in trailing response to the conductionof said other electric valve.

12. Apparatus comprising an alternating current supply circuit, a pair of electric valves each of which has an anode, a cathode, and a control element, means connecting the cathodes of said electric valves to the same potential of said supply circuit and the anodes of said electric valves to potentials of said supply circuits such that one of said electric valves may conduct during half cycles of voltage of one polarity and the other of said electric valves may conduct during half cycles of voltage of the opposite polarity, said means comprising an inductive circuit through each of said pair of electric valves whereby lagging current flows through the anode-cathode circuits of said electric valves, means for connecting the control elements of each of said electric valves in circuit with the trailing voltage. drop across the anode-cathode circuit of the other of said electric valves so that said pair of electric valves conduct alternately in trailing response to one another, means including a ca pacitor for timing the operating period of said. pair of electric valves, means including a secand capacitor for timing the non-operating period of said pair of electricvalves, charging and discharging circuits for each of'said capacitors,

25 means responsive to the conductivity of one of said pairs of electric valves for initiating the discharging of said first mentioned capacitor and the charging of said second capacitor and responsive to the non-conductivity of said one of said pairs of electric valves for initiating the charging of said first mentioned capacitor and the discharging of said second capacitor, means including a third electric valve for initiating conductivity of said one of said pair of electric valves,

said third electric valve having an anode, a cathode and a pair of control elements, means connected in the anode-cathode circuit of said third electric valve in parallel with the anode-cathode circuit of said other of said pairs of electric valves for conduction of current in the same direction through said inductive circuit of said other of said pair of electric valves, means for connecting one of said control elements of said third electric valve to said second capacitor and the other of said control elements to a source of potential rendering said third electric valve conducting at the beginning of a half cycle of its means for connecting the control element of said fourth electric valve through said first mentioned capacitor to render said fourth electric valve conducting when the potential of said capacitor has decreased to a predetermined value.

13. Apparatus comprising two electric valves each of which has an anode, a cathode, and a control element, a direct connection between the cathodes of said electric valves, means for sup-' plying alternating voltage to said electric valves so that one of said electric valves may conduct during half cycles of voltage of one polarity and the other of said electric valves may conduct during half cycles of voltage of the opposite polarity,

said means providing an inductive circuit through 7 one of said electric valves, means for introducing into the control element circuit of said one of said electric valves voltages rendering said one of said electric valves conducting and non-conducting when its anode voltage is positive, means including a timing capacitor for connecting the control element of said other of said electric valves to the anode connection of said one of said electric valves in its said inductive circuit, means 1 including an adjustable resistance'for controlling the discharge rate of said capacitor, and means for charging said capacitor comprising a hot cathode rectifier connected in circuit with said capacitor across the electrodes of a voltageregulating valve having one of its electrodes connected through a voltage-absorbing resistor to the anode connection of said one of said electric valves in its said inductive circuit and its other electrode connected to the common cathode con-' nection of said electric valves through a source of voltage opposing the self-generated voltage of said hot cathode rectifier and establishing the voltage of that terminal of said capacitor connected to the control element of said other of said'electric valves at a level higher than that of the common cathode connection of said electric valves.

14. Apparatus comprising an alternating current supply circuit. a load circuit, electric trans- 26 lating apparatus interconnecting said circuits and including an electric valve means having a control member, means including a first electric valve which when conductive applies to the control member of said electric valve means a component of voltage rendering said valve means conductive, said electric valve having an anode, a cathode, and a control element, means including a second electric valve which when conductive supplies to the control member of said electric valve means a component of voltage rendering said electric valve means non-conductive, said electric valve having an anode, a cathode, and a control element, a third electric valve having an anode, a cathode, and a control element, a direct connection between the cathodes of said first, second and third electric valves, means for connecting the anode-cathode circuits of said first and second electric valves with said supply circuit for conduction during half cycles of voltage thereof of one polarity and the anode-cathode circuit of said third electric valve in an inductive circuit with said supply circuit for conduction during half cycles of voltage thereof of the opposite polarity, means connecting the control element of said first electric valve to the anode connection of said third electric valve in its said inductive circuit for rendering said first electric valve conductive in response to the voltage drop across said third electric valve and in trailing fashion dependent on conduction of said third electric valve, means including a, timing capacitor for connecting the control element of said second electric valve to the anode connection of said third electric valve in its said inductive circuit, adjustable means connected across said 'in its said inductive circuit and its other electrode connected to the common cathode connection of said first, second, and third electric valves in circuit with a voltage opposing the self-generated voltage of said hot cathode rectifier and establishing the voltage level of the control element connection of said second electric valve with said capacitor at a value more positive than the cathode connection of said second electric 'valve.

15. Apparatus comprising an alternating current supply circuit, a circuit connected for energization from said supply circuit through the anode-cathode circuit of an electrical valve having a control element and a control element circuit, means including a timing capacitor connection in the control element circuit in said electrical valve, an adjustable discharge circuit for said capacitor, means including a hot cathode rectifier for charging said capacitor from said supply circuit and a source of voltage connected in series with said rectifier in said charging circuit for said capacitor for opposing the self-generation voltage of said rectifier and for establishing the voltage of the control element connection of said electric valve with said capacitor at a value more positive than the cathode connection of said electric valve.

16. Apparatus comprising an alternating current supply circuit, a circuit connected for energization from said supply circuit through the anode-cathode circuit-of an electrical valve havsaid electric valve and said cathode of said rectifier and in circuit with the filament of said rec tifier and means connecting'the primary winding of said transformer with said supply circuit for applying a voltage to the cathode of said rectifier that is positive relative to the cathode voltage of said electric valve and ,ofa value suificient to oppose the self-generating voltage of said rectifier.

, 1'7. Apparatus comprising an alternating currentsupplycircuit,acircuit connected for ener- -gization from said supply circuit through the anode-cathode circuit of an'electrical valve having a control element and a control element circuit, means including atiming capacitor connection ,in'the control "element circuit in said electrical valve, 'an adjustable discharge circuit for said capacitor, a voltage regulating valveconnected for energization from said supply circuit, means including a hot cathode rectifier con. nected in series with saidcapacitoracross said voltage regulating valvefor chargingsaidcapacitor to a predetermined voltage, said rectifier having an anode, a cathode, and a'control element, a cathode 'heater filament and'a control element, a filament heating transformer having primary-and secondary windings, means *for counsel n Said secondary, winding of said transformer between said cathode of said electric valve and said cathode or saidrectifier and' in circuit with the filament ofsaid rectifier means connecting the-primarywinding of said transformer .withsaidsupply circuit ior applying a voltage to ;the' cathode oisaid' rectifier that is positivere-lativetothe cathode voltage of said-electricvalve and of a valuesuificient-to'jqppose the -self-generatingvoltageof said rectifier, and means'for applying control potentials to the control element of said rectifier'that render said rectifier conductive only during a preselected midportion of the positive anode-potential of said rectifier.- I 18. Apparatus comprising an alternating cur- :rent supply circuit, a 'loa'd'circuit, electric translating apparatus interconnecting said circuits and including an electric valve having an anode,

a cathode and a control element, a control ele- 50 ment c i'rcuit for said electric-valve, three terminals connected withsaid supply circuit so that two of said terminals are of oppositepolarity relative to oneanotherarid to the third of said and secondary windings, means for connecting said primary winding of said control transformer in the control element circuit of said electric lvalve, means for connecting one terminal of the I primary winding of saidcontrol transformerto 'terminalsQa control transformer having primary" 65 'of said branch circuits, a second electric valve having an anode, a cathode and a control element and having its anode connected toward said other terminal of said primary Windingoi said control transformer, and means for applying c'ontrol potentials to the control element of said second electric valve to render said valve conducting and non-conducting and for reversing thereby'the phase of the control voltage applied to the control element of said first mentioned electric valve.

'19. Apparatus comprising an alternating current supply circuit, a load circuit, electric trans- -lati'ng apparatus interconnecting said circuits and including-an electric valve having an anode, a cathode and a control element, asecond electric valve having an anode, a cathode and a control element, means including said second electric valve for applying analternati'ng potential of said supply circuit to the control element of said'first mentioned electric valve and for reversing the phase of said potential each time said second electric valve becomes-conducting or non-conducting, initiating, keying, turn on, and timing electric valves, the sequential operation of which supplies control potentials tothe contro'lelement of said second electric element to render said second electric valve conducting or non-conduct- "ing, eachofsaid electric valves having an anode, a cathode and a control element and having :its -anode-cathode circuit connected' withrsaidsupply circuit, means including said initiating valve :for applying to the control. element of said-keying electric val've "a control potential rendering said keying electric valve conducting, means for applying to the control elementsof said keyingelec- -tric valve and said turn on electric valve control potentials for rendering said electric 'valves' conducting" alternately each in response to the con- -duction of theothen'tiniing me'ans becomingaeffective upon the initiation of conduction through said keying 'electric valve for rendering: said tim- "ing electric valve conducting after' a predetermi'ned timing delay, means responsive to the simultaneousconduction of i said turn on electric valve and said timing electric valve for rendering -saidkeying electric valve non-conducting,-and -means includingsaid initiating: electric valve for again rendering said-keying electric valve-conducting'after aip'redetermined timlng' delay.

-20.- Apparatus comprising an "alternating current supply. circuit, a load circuit,: ele ctric' translating apparatus interconnecting lsaid circu'its 'an'd including an electric valve having' an anode, a cathode '-and -'a- 'control element, acontrol' ele- --r'nent' circuit for said electric valve, I three termi- "nals 'connectedwith said supply circuit so that two er said terminals are of opposite polarity relative to" one another andto the third of said terminals," a control transformer: havin'gfprimary -and "scondary windings, means for connecting "said primary winding of said control transformer in the control element circuit =of :said -electric "valve; means fonconnectingmne terminal of tlie -prima'ry winding of said control transformer to said third terminal of said' 'supply circuit aiid its other terminal to' a switching circuit having' two -branches eachof which is connectedto adiirerent -one or said other terminals of said supply circuit, a current 5 limiting": element connected in one- 6f said *branch' circuits, a second electric valve :hav- --ing* an ariode, -aoathode and a eon tror elemefit and having its anode connected towardsaid other -termi-nal of1 said primary winding' of said control --transformer;initiating; keyingitum oni and tim- 29 ing electric valves each of which has an anode, a cathode and a control element, each of which has itsanode-cathode circuit connected with said supply circuit and the sequential operation of which applies control potentials to the control element of said second electric valve to render said second valve conducting and non-conducting and thereby reverse the phase of the control voltage applied to the control element of said first mentioned electric valve,'means including said initiating valve for applying to the control element of said keying electric valve a control potential rendering said keying electric valve conducting, means for applying to the control elements of said keying electric valve and said turn on electric valve control potentials for rendering said No references cited. 

